Board Porting Guide¶
To add Zephyr support for a new board, you at least need a board directory with various files in it. Files in the board directory inherit support for at least one SoC and all of its features. Therefore, Zephyr must support your SoC as well.
Boards, SoCs, etc.¶
Zephyr’s hardware support hierarchy has these layers, from most to least specific:
Board: a particular CPU instance and its peripherals in a concrete hardware specification
SoC: the exact system on a chip the board’s CPU is part of
SoC series: a smaller group of tightly related SoCs
SoC family: a wider group of SoCs with similar characteristics
CPU core: a particular CPU in an architecture
Architecture: an instruction set architecture
You can visualize the hierarchy like this:
Here are some examples. Notice how the SoC series and family levels are not always used.
Board |
SoC |
SoC series |
SoC family |
CPU core |
Architecture |
---|---|---|---|---|---|
nRF52832 |
nRF52 |
Nordic nRF5 |
Arm Cortex-M4 |
Arm |
|
MK64F12 |
Kinetis K6x |
NXP Kinetis |
Arm Cortex-M4 |
Arm |
|
STM32H747XI |
STM32H7 |
STMicro STM32 |
Arm Cortex-M7 |
Arm |
|
RV32M1 |
(Not used) |
(Not used) |
RI5CY |
RISC-V |
Make sure your SoC is supported¶
Start by making sure your SoC is supported by Zephyr. If it is, it’s time to Create your board directory. If you don’t know, try:
checking Supported Boards for names that look relevant, and reading individual board documentation to find out for sure.
asking your SoC vendor
If you need to add SoC, CPU core, or even architecture support, this is the wrong page, but here is some general advice.
Architecture¶
CPU Core¶
CPU core support files go in core
subdirectories under arch,
e.g. arch/x86/core.
See Set Up a Toolchain for information about toolchains (compiler, linker, etc.) supported by Zephyr. If you need to support a new toolchain, Build Overview is a good place to start learning about the build system. Please reach out to the community if you are looking for advice or want to collaborate on toolchain support.
SoC¶
Zephyr SoC support files are in architecture-specific subdirectories of soc. They are generally grouped by SoC family.
When adding a new SoC family or series for a vendor that already has SoC
support within Zephyr, please try to extract common functionality into shared
files to avoid duplication. If there is no support for your vendor yet, you can
add it in a new directory zephyr/soc/<YOUR-ARCH>/<YOUR-SOC>
; please use
self-explanatory directory names.
Create your board directory¶
Once you’ve found an existing board that uses your SoC, you can usually start by copy/pasting its board directory and changing its contents for your hardware.
You need to give your board a unique name. Run west boards
for a list of
names that are already taken, and pick something new. Let’s say your board is
called plank
(please don’t actually use that name).
Start by creating the board directory zephyr/boards/<ARCH>/plank
, where
<ARCH>
is your SoC’s architecture subdirectory. (You don’t have to put your
board directory in the zephyr repository, but it’s the easiest way to get
started. See Custom Board, Devicetree and SOC Definitions for documentation on moving your
board directory to a separate repository once it’s working.)
Your board directory should look like this:
boards/<ARCH>/plank
├── board.cmake
├── CMakeLists.txt
├── doc
│ ├── plank.png
│ └── index.rst
├── Kconfig.board
├── Kconfig.defconfig
├── plank_defconfig
├── plank.dts
└── plank.yaml
Replace plank
with your board’s name, of course.
The mandatory files are:
plank.dts
: a hardware description in devicetree format. This declares your SoC, connectors, and any other hardware components such as LEDs, buttons, sensors, or communication peripherals (USB, BLE controller, etc).Kconfig.board
,Kconfig.defconfig
,plank_defconfig
: software configuration in Kconfig formats. This provides default settings for software features and peripheral drivers.
The optional files are:
board.cmake
: used for Flash and debug supportCMakeLists.txt
: if you need to add additional source files to your build.One common use for this file is to add a
pinmux.c
file in your board directory to the build, which configures pin controllers at boot time. In that case,CMakeLists.txt
usually looks like this:if(CONFIG_PINMUX) zephyr_library() zephyr_library_sources(pinmux.c) zephyr_library_include_directories(${ZEPHYR_BASE}/drivers) endif()
doc/index.rst
,doc/plank.png
: documentation for and a picture of your board. You only need this if you’re Contributing your board to Zephyr.plank.yaml
: a YAML file with miscellaneous metadata used by the Sanity Tests.
Write your devicetree¶
The devicetree file boards/<ARCH>/plank/plank.dts
describes your board
hardware in the Devicetree Source (DTS) format (as usual, change plank
to
your board’s name). If you’re new to devicetree, see Introduction to devicetree.
In general, plank.dts
should look like this:
/dts-v1/;
#include <your_soc_vendor/your_soc.dtsi>
/ {
model = "A human readable name";
compatible = "yourcompany,plank";
chosen {
zephyr,console = &your_uart_console;
zephyr,sram = &your_memory_node;
/* other chosen settings for your hardware */
};
/*
* Your board-specific hardware: buttons, LEDs, sensors, etc.
*/
leds {
compatible = "gpio-leds";
led0: led_0 {
gpios = < /* GPIO your LED is hooked up to */ >;
label = "LED 0";
};
/* ... other LEDs ... */
};
buttons {
compatible = "gpio-keys";
/* ... your button definitions ... */
};
/* These aliases are provided for compatibility with samples */
aliases {
led0 = &led0; /* now you support the blinky sample! */
/* other aliases go here */
};
};
&some_peripheral_you_want_to_enable { /* like a GPIO or SPI controller */
status = "okay";
};
&another_peripheral_you_want {
status = "okay";
};
If you’re in a hurry, simple hardware can usually be supported by copy/paste followed by trial and error. If you want to understand details, you will need to read the rest of the devicetree documentation and the devicetree specification.
Example: FRDM-K64F and Hexiwear K64¶
This section contains concrete examples related to writing your board’s devicetree.
The FRDM-K64F and Hexiwear K64 board devicetrees are defined in frdm_k64fs.dts and hexiwear_k64.dts respectively. Both boards have NXP SoCs from the same Kinetis SoC family, the K6X.
Common devicetree definitions for K6X are stored in nxp_k6x.dtsi, which is included by both board .dts
files. nxp_k6x.dtsi in turn includes
armv7-m.dtsi, which has common definitions
for Arm v7-M cores.
Since nxp_k6x.dtsi is meant to be
generic across K6X-based boards, it leaves many devices disabled by default
using status
properties. For example, there is a CAN controller defined as
follows (with unimportant parts skipped):
can0: can@40024000 {
...
status = "disabled";
...
};
It is up to the board .dts
or application overlay files to enable these
devices as desired, by setting status = "okay"
. The board .dts
files are also responsible for any board-specific configuration of the device,
such as adding nodes for on-board sensors, LEDs, buttons, etc.
For example, FRDM-K64 (but not Hexiwear K64) .dts
enables the CAN
controller and sets the bus speed:
&can0 {
status = "okay";
bus-speed = <125000>;
};
The &can0 { ... };
syntax adds/overrides properties on the node with label
can0
, i.e. the can@4002400
node defined in the .dtsi
file.
Other examples of board-specific customization is pointing properties in
aliases
and chosen
to the right nodes (see Aliases and chosen nodes), and
making GPIO/pinmux assignments.
Write Kconfig files¶
Zephyr uses the Kconfig language to configure software features. Your board needs to provide some Kconfig settings before you can compile a Zephyr application for it.
Setting Kconfig configuration values is documented in detail in Setting Kconfig configuration values.
There are three mandatory Kconfig files in the board directory for a board
named plank
:
boards/<ARCH>/plank
├── Kconfig.board
├── Kconfig.defconfig
└── plank_defconfig
Kconfig.board
Included by boards/Kconfig to include your board in the list of options.
This should at least contain a definition for a
BOARD_PLANK
option, which looks something like this:config BOARD_PLANK bool "Plank board" depends on SOC_SERIES_YOUR_SOC_SERIES_HERE select SOC_PART_NUMBER_ABCDEFGH
Kconfig.defconfig
Board-specific default values for Kconfig options.
The entire file should be inside an
if BOARD_PLANK
/endif
pair of lines, like this:if BOARD_PLANK # Always set CONFIG_BOARD here. This isn't meant to be customized, # but is set as a "default" due to Kconfig language restrictions. config BOARD default "plank" # Other options you want enabled by default go next. Examples: config FOO default y if NETWORKING config SOC_ETHERNET_DRIVER default y endif # NETWORKING endif # BOARD_PLANK
plank_defconfig
A Kconfig fragment that is merged as-is into the final build directory
.config
whenever an application is compiled for your board.You should at least select your board’s SOC and do any mandatory settings for your system clock, console, etc. The results are architecture-specific, but typically look something like this:
CONFIG_SOC_${VENDOR_XYZ3000}=y /* select your SoC */ CONFIG_SYS_CLOCK_HW_CYCLES_PER_SEC=120000000 /* set up your clock, etc */ CONFIG_SERIAL=y
Build, test, and fix¶
Now it’s time to build and test the application(s) you want to run on your board until you’re satisfied.
For example:
west build -b plank samples/hello_world
west flash
For west flash
to work, see Flash and debug support below. You can
also just flash build/zephyr/zephyr.elf
, zephyr.hex
, or
zephyr.bin
with any other tools you prefer.
General recommendations¶
For consistency and to make it easier for users to build generic applications that are not board specific for your board, please follow these guidelines while porting.
Unless explicitly recommended otherwise by this section, leave peripherals and their drivers disabled by default.
Configure and enable a system clock, along with a tick source.
Provide pin and driver configuration that matches the board’s valuable components such as sensors, buttons or LEDs, and communication interfaces such as USB, Ethernet connector, or Bluetooth/Wi-Fi chip.
If your board uses a well-known connector standard (like Arduino, Mikrobus, Grove, or 96Boards connectors), add connector nodes to your DTS and configure pin muxes accordingly.
Configure components that enable the use of these pins, such as configuring an SPI instance to use the usual Arduino SPI pins.
If available, configure and enable a serial output for the console using the
zephyr,console
chosen node in the devicetree.If your board supports networking, configure a default interface.
Enable all GPIO ports connected to peripherals or expansion connectors.
If available, enable pinmux and interrupt controller drivers.
It is recommended to enable the MPU by default, if there is support for it in hardware. For boards with limited memory resources it is acceptable to disable it. When the MPU is enabled, it is recommended to also enable hardware stack protection (CONFIG_HW_STACK_PROTECTION=y) and, thus, allow the kernel to detect stack overflows when the system is running in privileged mode.
Flash and debug support¶
Zephyr supports Building, Flashing and Debugging via west extension commands.
To add west flash
and west debug
support for your board, you need to
create a board.cmake
file in your board directory. This file’s job is
to configure a “runner” for your board. (There’s nothing special you need to
do to get west build
support for your board.)
“Runners” are Zephyr-specific Python classes that wrap flash and debug
host tools and integrate with west and the zephyr build
system to support west flash
and related commands. Each runner supports
flashing, debugging, or both. You need to configure the arguments to these
Python scripts in your board.cmake
to support those commands like this
example board.cmake
:
board_runner_args(nrfjprog "--nrf-family=NRF52")
board_runner_args(jlink "--device=nrf52" "--speed=4000")
board_runner_args(pyocd "--target=nrf52" "--frequency=4000000")
include(${ZEPHYR_BASE}/boards/common/nrfjprog.board.cmake)
include(${ZEPHYR_BASE}/boards/common/jlink.board.cmake)
include(${ZEPHYR_BASE}/boards/common/pyocd.board.cmake)
This example configures the nrfjprog
, jlink
, and pyocd
runners.
Warning
Runners usually have names which match the tools they wrap, so the jlink
runner wraps Segger’s J-Link tools, and so on. But the runner command line
options like --speed
etc. are specific to the Python scripts.
For more details:
Run
west flash --context
to see a list of available runners which support flashing, andwest flash --context -r <RUNNER>
to view the specific options available for an individual runner.Run
west debug --context
andwest debug --context <RUNNER>
to get the same output for runners which support debugging.Run
west flash --help
andwest debug --help
for top-level options for flashing and debugging.See Flash and debug runners for Python APIs.
Look for
board.cmake
files for other boards similar to your own for more examples.
To see what a west flash
or west debug
command is doing exactly, run it
in verbose mode:
west --verbose flash
west --verbose debug
Verbose mode prints any host tool commands the runner uses.
The order of the include()
calls in your board.cmake
matters. The
first include
sets the default runner if it’s not already set. For example,
including nrfjprog.board.cmake
first means that nrjfprog
is the default
flash runner for this board. Since nrfjprog
does not support debugging,
jlink
is the default debug runner.
Contributing your board¶
If you want to contribute your board to Zephyr, first – thanks!
There are some extra things you’ll need to do:
Make sure you’ve followed all the General recommendations. They are requirements for boards included with Zephyr.
Add documentation for your board using the template file doc/templates/board.tmpl. See Documentation Generation for information on how to build your documentation before submitting your pull request.
Prepare a pull request adding your board which follows the Contribution Guidelines.